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Students’ Extrinsic and Intrinsic Motivation Level and Its Relationship with Their
Mathematics Achievement
Meltem ACAR GÜVENDİR1
Abstract
This study focused on the extrinsic and intrinsic motivation levels of eighth grade students
and its relationship with their mathematical achievement. The participants of the study included
6829 students who took TIMSS in 2011 and 239 mathematics teachers. The data obtained from
the student and teacher questionnaires that are included in the content of TIMSS exam were used.
Two-level HLM was used to examine how students’ mathematics achievement is related to their
extrinsic and intrinsic motivation levels. One way ANOVA with Random effects, Means as
Outcomes Regression Model, The Random Coefficient Regression Model were used in the two
level HLM. The study results show that students’ mathematics interest, self-efficacy, perceptions
of mathematics, and the frequency of mathematics exams and teachers’ interest in students at
schools are related to mathematics achievement. The examination of the effect size of the
variables particularly shows that intrinsic motivational variables have a stronger relationship with
mathematics achievement than extrinsic motivational variables. The overall analysis of the study
findings shows that mathematics achievement is related to both intrinsic and extrinsic
motivational resources that need to be addressed by mathematics experts and teachers.
Key Words: Mathematics achievement, TIMSS, motivation, hierarchical linear modeling,
extrinsic and intrinsic motivation.
Introduction
Mathematics is a human activity, a social phenomenon, a set of methods used to help
illuminate the world and it is part of culture (Boaler, 2008). “Mathematics is the backbone of
modern science and a remarkably efficient source of new concepts and tools to understand the
“reality” in which we participate. It plays a basic role in the great new theories of physics of the 1 Assistant Prof. Dr. Faculty of Education, Trakya University, [email protected]
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XXth century such as general relativity and quantum mechanics” (Connes, 2005, p. 01). “What
mathematics offers is a way of doing things: to be able to solve mathematical problems, and more
generally, to have the right attitude for problem solving and to be able to confront all kinds of
problems in a systematic manner” (National Council for Educational Research and Training,
2006). Children who do learn about the true nature of mathematics are very fortunate and it often
shapes their lives. Thus, mathematics is a crucial course for students since mathematical skills are
important job skills and useful in everyday life. Betz (1978) stresses that mathematics is one of
the most important tools that human beings must possess in order to adapt to the developing and
changing world.
According to the American National Research Council’s report (1989) expertise in most
occupations requires at least a basic knowledge of mathematics and geometry. Tobias (1978)
stated that mathematical knowledge is a key factor that increases the chances of employment in
recruitment exams done by the army, private, and government institutions. Therefore, one of the
primary goals of education should be to make students reach high competence in mathematics
(Tall and Razali, 1993). Considering the importance of mathematics for students and individuals,
national policy makers, educators, and researchers have been examining factors that may have
meaningful and consistent relationships with mathematical achievement. One factor that has
received considerable attention is motivation. “To be motivated means to be moved to do
something. A person who feels no impetus or inspiration to act is thus characterized as
unmotivated, whereas someone who is energized or activated toward an end is considered
motivated” (Ryan and Deci, 2000, p.54). Studies on mathematics show that students should have
high motivation in order to achieve a high standard of mathematical education. Students who
have high motivation take education more seriously, participate in classroom activities, consider
teachers’ recommendations, and have higher academic achievement scores (Pajares and Schunk,
2001; Wolters and Rosenthal, 2000). Motivation also makes students display their real potential
(Eggen and Kauchak, 1997). Thus, motivating students to be enthusiastically receptive is one of
the most important aspects of mathematics instruction.
Motivation is a complex psychological construct that attempts to explain behavior and the
effort applied in different activities (Watters and Ginns, 2000). Motivation involves extrinsic
rewards that occur outside the learner's control and intrinsic goals in their desire to achieve a
particular target. While physical reward, punishment, social pressure, higher social expectations,
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homework, and classroom competition are items of extrinsic motivation (Moore, 2001), intrinsic
motivation includes factors such as attitude, value, needs, and the desire to become competent
(Moore, 2001; Pintrich and De Groot, 1990). Intrinsic motivation is regulated by the individual
himself. According to Deci (1972), a person is intrinsically motivated to perform an action if
there is no apparent incentive except the action itself or the feelings which result from the
activity. However, in extrinsic motivation, environment is the central controlling mechanism and
the person’s motivation is regulated by the outside rewarding mechanisms that s/he considers as a
reward (Newstrom and Davis, 2002; Wu, 2003).
In mathematics education, student motivation plays a key role, (Gelman and Greeno, 1989;
Hannula, 2006; Middleton and Spanias, 1999; Singh, Granville, and Dika, 2002; Walker and
Guzdial, 1999) and mathematical achievement is related to both intrinsic and extrinsic
motivational factors. Research has shown that intrinsic motivation leads to self-efficacy (Pajares,
1996) which is a clear predictor of students’ academic performance in mathematics (Alliman-
Brissett and Turner, 2010; Mousoulides and Philippou, 2005). Intrinsically motivated students are
not discouraged by more complex problems (Middleton and Spanias, 1999) and they spend more
time on-task, tend to be more persistent, and are confident in using different, or more challenging,
strategies to solve mathematical problems (Lepper, 1988; Lepper and Henderlong, 2000).
Students who are highly intrinsically motivated to study mathematics increase their achievement,
their determination in the face of disappointment, and their confidence (Lehmann, 1986; Pokay
and Blumenfeld, 1990). Mathematics courses can be arduous and intrinsic motivation can
energize children to invest the effort and utilize the strategies necessary to be successful
(Froiland, Oros, Smith, and Hirchert, 2012). In a large scale study using TIMSS data, Mullis et al.
(2000) found that students who show positive attitudes toward mathematics and display signs of
intrinsic motivation were more likely to get higher scores. Intrinsically motivated students are
more likely than their peers to use effective mathematics strategies such as estimating,
visualizing, and checking (Montague, 1992). Middleton, Littlefield, and Lehrer (1992) found that
students’ intrinsic motivation to learn mathematics is highly influenced by the classroom tasks
designed by the teacher. The authors conclude that mathematics activities must be difficult
enough that students are not bored, yet tasks must allow for a high degree of success given
appropriate effort by the student. Similarly, Boaler (1999) reported a relationship between
meaningful mathematical tasks and student intrinsic motivation. Accordingly, when given the
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opportunity to engage in meaningful mathematical tasks that maintain their cognitive integrity,
students not only tolerate mathematical work, but express pleasure and satisfaction.
In contrast to the intrinsic motivation which is related to internal rewards, extrinsically
motivated students engage in learning for external rewards, such as teacher and peer approval,
and good grades (Mueller, Yankelewitz, and Maher, 2012). According to Middleton and Spanias
(1999), extrinsically motivated students do not necessarily have a sense of ownership of the
mathematics that they study; instead they focus on praise and interest from teachers, parents and
peers and avoiding punishment or negative feedback. It is typically believed that intrinsic
motivation tends to be deeper and more influential than the extrinsic one and its corresponding
effect also continues longer (Zhu and Leung, 2011). Several researchers (e.g., Deci, 1971; Deci,
Koestner, and Ryan, 1999; Kruglanski, Friedman, and Zeevi, 1971; Lepper, Greene, and Nisbett,
1973; Lepper and Henderlong, 2000) contend that extrinsic rewards undermine existing intrinsic
motivation. According to Zhu and Leung (2011, p. 1191-1192) “the argument about the
superiority of intrinsic motivation usually relates to its nature, that is, it originates from within the
individual and is independent of external influences. In contrast, researchers viewed the
temporariness as one serious drawback of extrinsic motivation, that is to say, such motivation
would disappear as soon as the reward or punishment was withdrew.” Despite the negative ideas
on extrinsic motivation, several researchers argued that extrinsic motivation triggers the intrinsic
motivation rather than undermining it and it has positive effects especially when students have
low levels of intrinsic motivation (Brophy, 2004; Cameron, 2001; Lepper, Corpus and Lyengar,
2005).
Considering the conflicting arguments on the importance of intrinsic and extrinsic
motivation and their relation to mathematics, it is significant to conduct large scale studies that
examine these two different motivation types and compare the degree of their relation to
mathematics achievement. Hence, this study aims to examine students’ intrinsic and extrinsic
motivation levels and their relationship with mathematics achievement and handles the following
research questions:
1. Does students’ mathematics achievement vary according to external resource levels?
2. What are the intrinsic resources that are related to students’ mathematics achievement?
3. What are the extrinsic resources that are related to students’ mathematics achievement?
4. Which motivation type is more related to students’ mathematics achievement?
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By providing results from a large group of participants from the Turkish context, it is hoped
that the study will contribute to the research that examines and compares intrinsic and extrinsic
motivational variables and their relationship with mathematics achievement simultaneously and
provide actionable guidelines for researchers and educational practitioners.
Method
Research Model
In this study, the student and teacher characteristics that are related to students’
mathematics achievement are determined. Thus, this study follows a relational screening model.
Sample and Population
In this study, Mathematics and Science Study (TIMSS) 2011 data were used. Therefore,
the sample and population specified by TIMSS were used. Since the study aims to examine
students’ intrinsic and extrinsic motivation levels and their relationship with mathematics
achievement, it uses TIMSS 2011 student data for intrinsic motivation levels and TIMSS 2011
teacher data for extrinsic motivation levels. In this respect, the population of the study includes
eighth grade students enrolled in schools of secondary education in Turkey during the 2011
educational year and mathematics teachers. The sample of the study includes 6826 students who
took TIMSS in 2011 and 239 mathematics teachers. The data for the study was obtained from
TIMSS web page (http://timss.bc.edu/).
Data Collection Tools
In this study, the data obtained from the student and teacher questionnaires that are
included in the content of TIMSS exam were used. TIMSS 2011 student questionnaire has six
items on mathematics interest, nine items on self-efficacy, and five items on students’ general
perceptions of mathematics. Mathematics interest in the student questionnaire includes clauses
such as “I enjoy learning mathematics”, and “I like mathematics”. On the other hand, the self-
efficacy section in the TIMSS 2011 student questionnaire has clauses such as “I can easily learn
mathematics,” and “Mathematics is easier than other courses”. The general perceptions of
mathematics section include clauses primarily about the use of mathematics in real life. These
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clauses are; “I think I will use mathematics in my daily life” and “In order to have a job I need to
have a sufficient knowledge of mathematics”.
In the teacher questionnaire, the “exam” variable was taken into consideration. In relation
to this variable the questionnaire includes the clause “how often do the students have
mathematics exams?” Additionally, the questionnaire includes an item on the interest displayed
by the teacher for the students. “I explain the answers of the questions” and “I help my students
find the best techniques to solve complex questions” clauses are related to this item (Mullis and
Martin, 2011).
In TIMSS 2011 mathematics achievement is determined by mathematics achievement tests.
The achievement tests generally cover the basic skills that are practiced in education programs.
Mathematics achievement test in TIMSS 2011 includes questions about mathematical knowledge,
mathematical processes, the ability to use complex mathematical processes, problem solving,
problem identifying, and mathematical judgment (Foy, Arora, and Stanco, 2013).
Data Analysis
Two-level HLM was used to examine how students’ mathematics achievement is related to
their extrinsic and intrinsic motivation levels.
The Level 1 (student level) involves data from the student questionnaire. The variables
“interest”, “self-efficacy”, and “perception” are related to intrinsic motivation. The Level 2
(teacher or classroom level) level involves data from the teacher questionnaire. The variables
“exam” and “interest in the student” are related to extrinsic motivation.
The majority of data obtained in social sciences, is nested and has a hierarchical structure
(Atar, 2010). Measurement in education focuses on student variables which are achievement,
attitude, ability, and proficiency. Student variables can vary according to some factors. These
factors can stem from classrooms and schools in which the students have educational experiences
(Hox, 1995). In education, research has shown that students are nested in classrooms; classrooms
are nested in schools, schools within cities, cities within regions, and regions within countries.
Hence, most of the data gathered from studies conducted in social sciences are entwined, and
thus, display a hierarchical structure (Hox, 1995; O’Connel and McCoach, 2008; Osborne, 2002;
Raudenbush and Bryk, 2002; Snijders and Bosker, 1999). Doing unilevel analysis instead of
multilevel analysis for the data which has a hierarchical structure is not suitable, as such an
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operation will violate the independence of the observations in the data set with other observations
in the data set (Hox, 1995). Students cannot be considered distinct from classrooms, classes from
schools, schools from districts, and districts from countries. Therefore, using a Hierarchical
Linear model for hierarchical data analysis will provide more comprehensive and detailed results
(Hox, 2002; O’Connell and McCoach, 2008; Osborne, 2002; Raudenbush and Bryk, 2002;
Snijders and Bosker, 1999). This research uses HLM as the data gathered from TIMSS 2011 is
entwined and displays a hierarchical structure.
One way ANOVA with Random effects, Means as Outcomes Regression Model, and The
Random Coefficient Regression Model are used in two level HLM. As Raudenbush and Bryk,
(2002, p.26) put it, “the simplest possible hierarchical linear model is equivalent to a one-way
ANOVA with random effects. This model is fully unconditional i.e. no predictors are specified at
either level 1 or 2. Means as outcomes regression model demonstrates whether means from each
of many groups as an outcome to be predicted by group characteristics. One-way ANOVA and
means-as-outcomes sub models were random-intercept models and only the level-1 intercept
coefficient, was viewed as random. Regression slopes did not exist in those models. However, a
major class of applications of hierarchical linear models conceives level-1 slopes as varying
randomly over the population of level-2 units. Random coefficients regression model is the
simplest case of this type. In these models, both the level-1 intercept and one or more level-1
slopes vary randomly, but no attempt is made to predict this variation.”
While SPSS 17.0 and Microsoft Excel 2010 were used for data organization, HLM 7.0
was used for the hierarchical linear model. The level of the statistics obtained from the study was
considered as minimum .05 in the significance test. Table 1 shows the descriptive statistic values
related to variables.
Table 1. Descriptive Statistics Variable N Mean Standard Deviation Minimum Maximum
Outcome Variable
Mat. Achievement 6826 449.97 106.61 142.85 844.40
Explanatory Variable
Interest, γ10 6826 18.45 4.36 .00 24.00
Self-Efficacy, γ20 6826 20.28 4.66 .00 32.00
Perception, γ30 6826 14.77 3.74 5.00 20.00
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Exam, γ01 239 3.25 .68 2.00 5.00
Interest in student, γ02 239 34.45 5.87 .00 44.00
Findings
Two-level HLM was used to examine how students’ mathematics achievement is related
to their extrinsic and intrinsic motivation levels. One way ANOVA with Random Effects, Means
as Outcomes Regression Model, and The Random Coefficient Regression Model were used
respectively in HLM.
Table 2 displays the correlation values between the outcome variable and the explanatory
variables that show the intrinsic motivation levels at the student level.
Table 2. The correlation values between the outcome variable and the explanatory
variables
Interest Self-Efficacy Perception Achievement
Interest
Self-Efficacy .62*
Perception .55* .48*
Achievement .32* .48* .21*
Exam Interest in student Achievement
Exam
Interest in student .05*
Achievement .08* .10*
*p<.01
Table 2 displays the correlation values between the variables at the student level (intrinsic
motivation level). The correlation between explanatory variables is higher than the correlation
between the outcome variable and the explanatory variables. On the other hand, the relationship
between the variables at the classroom level (extrinsic motivation level) is low. There is a low but
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significant relationship between the variables at the classroom level (extrinsic motivation level)
and the outcome variable.
Equations formed in HLM and the findings are as follows:
Level 1 Model
MATij = β0j + β1j*(Interestij) + β2j*(self-efficacy ij) + β3j*(Perceptionij) + rij
Level 2 Model
β0j = γ00 + γ01*(Examj) + γ02*(Interest in studentj) + u0j
Table 3. HLM results of the students’ Mathematics achievement
Parameter One Way
ANOVA Level 1 Model Level 2 Model
Fixed effects Coefficient Standart Error t-ratio Coefficient Standart
Error t-ratio
Effect
Size Coefficient
Standart
Error t-ratio
Effect
Size
Level 1
Intercept, γ00 450.39 4.16* 108.32 450.42 4.16* 108.31 450.41 4.09* 110.12
Interest, γ10 - - 1.99 .33* 5.98 .36
Self-Efficacy,
γ20 - - 9.77 .34* 28.90 .88
Perception,
γ30 - - 1.54 .33* 4.61 .28
Level 2
Exam, γ01 - - 12.30 6.09** 2.01 .13
Interest in
student, γ02 - - 2.92 1.27** 2.30 .15
Random
effects
Standart
Deviation Var.Com.*** χ2
Standart
Deviation Var.Com. χ2
Standart
Deviation Var.Com. χ2
Relability
estimate
Intercept, u0 61.96 3838.82 3521.48* 62.67 3929.78 4859.36* 60.87 3705.56 3367.82* .95
Interest, u1j 2.35 5.50 317.73* .19
Efficacy, u2j 3.18 10.12 378.99* .35
Perception,
u3j 177.54 3.15 274.21** .11
Level 1, r 87.60 7674.04 72.94 5320.13 87.60 7674.14 1Before the analysis the classroom level variables (extrinsic motivation level variables) were centered around the grand mean,
student level variables (intrinsic motivation level variables) were centered around the group mean.
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*p < .01. ** p < .05.
***Var.Com.=variance component
According to the one way ANOVA with random effects in Table 3, the mean mathematics
achievement for all classes was estimated as t= 108.32 with the ratio γ00= 450.39. These results
show that the fixed parameters are significant (χ2=3521.48, df=238, p<.01). Thus, mathematics
achievement displays a significant difference among classes according to the external resources.
95% confidence interval for the mean mathematics achievement is as follows:
Confidence Interval= 108.32 ± 1.96 (.91)
(107.41 ≤ γ00 ≤ 109.23)
The one-way ANOVA random effects model splits the total variance that belongs to the
mathematics achievement score into two components. These components are the variance among
students in classrooms (Level-1) and the variance among the classrooms (Level-2). These
components are demonstrated as follows:
σ2 / (σ2 + τβ) = 7674.04/ (7674.04+ 3838.82) = .67
τ00 / (σ2 + τ00) = 3838.82/ (3838.82+ 7674.04) = .33
According to these results, while 67% of the total variance stems from the difference
among students’ intrinsic motivation levels, 33% is caused by the difference between the
extrinsic motivation levels. The value .33 also shows the correlation coefficient (p) within the
classrooms (extrinsic motivation level).
The random coefficient regression model (model 1) findings on Table 3 show that variables
that belong to students’ intrinsic motivation level (interest, self-efficacy, and perception) are
related to their mathematics achievement.
The coefficient values that belong to the mathematics interest variable shows that there is a
positive significant relationship between mathematics interest and mathematics achievement
(γ01=1.99, SE=.33, p<.01). Thus, students who show interest in mathematics are better achievers.
There is also a positive significant relationship between self-efficacy and mathematics
achievement (γ02=9.77, SE=.34, p<.01). Accordingly, the students who think they have sufficient
potential to learn mathematics have higher mathematics scores. The study results display that
there is a positive significant relationship between students’ perceptions of mathematics and
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mathematics achievement scores (γ03=1.54, SE=.33, p<.01). In this sense, students who have
positive perceptions about mathematics course have higher achievement scores than the students
who have negative perceptions. In other words, the students who think that mathematics is useful
for daily life experiences have high mathematics scores.
Of the three variables of intrinsic motivation, the one that has the highest relationship with
mathematics achievement is the self-efficacy variable. Compared to other intrinsic motivation
variables, the perception of mathematics variable has a lower relationship with mathematics
achievement. Additionally, 31% of the student achievement within the classroom can be
described by the intrinsic motivation variables (student level variables).
In level two “the frequency of exams in mathematics courses” and “the interest shown by
the teacher to the student” were considered for the students’ extrinsic motivation. The
relationship between these variables and mathematics achievement was examined. The study
results show that there is a positive significant relationship between the frequency of exams and
mathematics achievement (γ01=12.30, SE=6.09, p<.05). Thus, as the teacher increases the number
of mathematics exams, the students’ mathematics scores also increase. The study results also
display a significant relationship between teacher’s interest shown to the student and mathematics
achievement (γ02=2.92, SE=1.27, p<.05). Furthermore, 3% of the classroom means variance can
be described by the extrinsic motivation level variables (classroom level variables).
The reliability values of the variables in Table 3 show that the reliability value that belongs
to the fixed is high (.95). This result indicates that 0j, the mean mathematics achievement in the
classrooms (extrinsic motivation level), is a reliable predictor.
Of the level one explanatory variables self-efficacy variable (self-efficacy, γ2=.35) has the
highest reliability. Self-efficacy is followed by the mathematics interest variable (Interest,
γ1=.19). Perception variable has the lowest reliability value (Perception, γ3=.11). The reliability
predictions being more than .05 show that these coefficients vary randomly among classrooms.
When the effect size of the variables are examined, the variable that has the highest
relationship with mathematics achievement is self-efficacy (effect size=.88), followed by interest
(effect size=.36), perception (effect size=.28), interest in student (effect size=.15), and exam (effect
size=.13). These results display that intrinsic motivational variables have higher effect sizes than
the extrinsic motivation variables.
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CONCLUSION AND DISCUSSION
In the HLM conducted, initially the three variables of intrinsic motivation and subsequently
two variables of extrinsic motivation were included in the model. The study results show that all
the variables of the intrinsic motivation and extrinsic motivation are related to students’
mathematics achievement. However, a comparison between the variables of extrinsic and
intrinsic motivation shows that the relationship between intrinsic motivational factors and
mathematical achievement is higher than the extrinsic ones. This finding corresponds with the
research findings that stress the superiority of intrinsic motivation over extrinsic motivation in
mathematics achievement (Zhu and Leung, 2011). In this sense, this finding strengthens the
argument that mathematics education should aim to increase students’ intrinsic motivation in
order to help students achieve success in mathematics. Increasing intrinsic motivational levels of
student is an intricate process that assigns different roles to parents, teachers, and educational
policy makers. According to Davidson et al. (2007) interesting and challenging activities that are
personally meaningful help to cultivate intrinsic motivation. Inquiry based learning that integrates
group work and discovery also assists intrinsic motivation. Intrinsic motivation is affected by
adults, including parents, teachers, and other adults with whom the student has a connection.
Parents with high expectations but a positive attitude tend to have more intrinsically motivated
children. A considerate and respectful teacher student relationship can foster intrinsic motivation.
Having a choice of positive extracurricular activities also improves motivation in the classroom.
Behavior of school administrators can also influence teacher motivation, which in turn can
influence student motivation; when teachers feel that they have a voice in decision making they
feel more motivated.
A noteworthy finding of the study is the relationship between self-efficacy and mathematics
achievement. The literature on mathematics and self-efficacy provides parallel findings (Alliman-
Brissett and Turner, 2010; Bourquin, 1999; Lane and Lane, 2001; Migray, 2002; Mousoulides
and Philippou, 2005; Otunuku and Brown, 2007; Pietsch, Walker, and Chapman, 2003; Stevens,
Olivarez, and Hamman, 2006; Wilkins, 2004; Zimmerman, 2000) and self-efficacy is often
regarded as a byproduct of intrinsic motivation (Pajares, 1996). These study results show that the
students who think they have enough potential to cope with mathematics have higher
mathematics scores than the students who do not feel any potential to learn mathematics. This
variable also has the highest relationship with mathematical achievement. Thus, students who
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think that they have no mathematical potential should be motivated and supported to discover
their underlying potential.
According to the study results, the students who are interested in mathematics have better
test scores. Similarly, Singh, Granville, and Dika (2002), Shin, Lee, and Kim (2009), and Cai-
zhen (2008) found a high correlation between mathematical interest and mathematical
performance. In another study, Bayturan (2004) found that students who are interested in
mathematics enjoy mathematics classes, participate in mathematics classroom activities, consider
being successful in mathematics as crucial, and find the mathematics courses interesting.
Conversely, students who are not interested in mathematics had lower scores and displayed none
of these features. These results show that it is important for teachers to recognize their students
and have an awareness of their mathematical interests. As Osborne, Simon, and Collins (2003)
stated teachers should use suitable activities for their classes and students so that students who are
not interested in the subject matter and who have negative attitudes can display positive
transformations. In addition to teachers, families also have key roles in increasing students’
interest rates about various subjects (Kawiak, 2013). Therefore, both teachers and parents should
cooperate to increase students’ interest levels (Rice et al., 2013).
The study findings reveal that students who think mathematics is useful for their daily life
activities have better mathematical test scores than the students who consider mathematics
unnecessary for daily life. According to Schiefele and Csikszentmihalyi (1995) and Singh,
Granville, and Dika (2002) students’ perceptions about a course has a relationship with their
achievement scores. Marsh, Craven, and Debus (1999) demonstrated that cognitive and affective
self-perceptions were highly correlated. Boaler (1999) also reported that when students engage in
meaningful mathematical tasks that they can relate to real life experiences, they find mathematics
an enjoyable subject to study. On the other hand, Akyüz and Satıcı (2013) claim that students'
mathematics perceptions and mathematics achievement have a negative relationship.
Correspondingly, in this study mathematics perception has the lowest correlation with
mathematic achievement. In this sense, further research which examines reasons for the
relationship between mathematics perception and achievement should be conducted.
According to the study results there is a relationship between the interest shown by the
teacher to the student and mathematical achievement. Similarly, according to Program for
International Student Assessment (PISA) 2000 results the disciplinary climate and teacher’s
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interest have an influence on students’ performance (Organisation for Economic Co-operation
and Development-OECD, 2001). Osseiran-Waines and Almacian (1994), Cutrona, Cole,
Colangelo, Assouline, and Russell (1994), Levitt, Guacci-Franco, and Levitt (1994), and Meeus
(1993) reveal a relationship between teacher’s support and academic achievement. According to
Ladd (1990) students who are supported by their families and teachers can adapt to schools easily
and have higher tests scores. On the contrary, Bos and Kuiper (1999) found class climate and
teacher’s interest did not show significant relationships with mathematical achievement in the
most of the models of European countries. Although there are contradictory findings on teacher’s
interest and student achievement the studies in general show that teacher’s and families’ interest
can be important not only for academic achievement but also for student adaptation and devotion.
The study results also display a relationship between exam frequency and mathematical
achievement. Amrai, Mothlag, Zalani, and Parhon (2011) argue that extrinsic motivation
variables such as exam and grading are related to academic achievement in general. In a study
Akyüz (2006) found that the relationship between mathematical literacy and exam frequency
varies from country to country. For instance, in Hungary, Lithuania, and Holland students had
lower mathematics achievement scores as the number of the exams increased. Conversely,
Turkish students had higher scores if they were exposed to mathematics exams more frequently.
Although exams are frequently used to increase the external motivation of the students, it should
be kept in mind that having low scores from these exams may demoralize the students and have
negative effects.
The overall analysis of the study findings shows that mathematical achievement is related
to both intrinsic and extrinsic motivational resources that need to be considered by mathematics
practitioners, educators, and policy makers. However, the examination of the effect size of the
variables particularly shows that intrinsic motivational factors have a higher relationship with
mathematical achievement than extrinsic motivational factors. Hence, activities and regulations
should be put into practice in order to intrinsically motivate the students who have low or no
motivation so that mathematical achievement can be ensured. Stipek et al. (1998) pointed out that
in order to increase intrinsic motivation, teachers should use positive verbal feedback, focus on
deep understanding rather than performance goals, provide multiple ways of finding solutions
and support risk-taking when problem-solving rather than chastising children for getting the
problem wrong. As Froiland, Oros, Smith, and Hirchert (2012, p.94) state, “both math reform
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experts and motivational experts are calling for teachers to use an autonomy supportive style of
instruction. In accordance, school psychologists can consult with teachers to show them how to
adopt an autonomy supportive teaching style in the mathematics classroom”.
It is important to note that the current study is limited to the Turkish context and the
findings need to be considered within the scope of Turkey. However, this study can provide the
potential for comparative examinations with results coming from different countries. Another
limitation of the study is its focus on only the TIMSS data. Hence, other large scale data such as
PISA could be examined in order to see how motivational factors are related to mathematics
achievement.
REFERENCES
Akyüz, G. (2006). Türkiye ve Avrupa birliği ülkelerinde öğretmen ve sınıf niteliklerinin matematik başarısına etkisinin incelenmesi. İlköğretim Online, 5 (2), 61-74.
Akyüz, G. & Satıcı, K. (2013). PISA 2003 verilerine göre matematik okuryazarlığının çeşitli değişkenler açısından incelenmesi: Türkiye ve Hong Kong-Çin modelleri. Kastamonu Eğitim Dergisi, 21, No:2.
Alliman-Brissett, A., & Turner, S. (2010). Racism and math-based career interests, efficacy, and outcome expectations among African American adolescents. Journal of Black Psychology, 36, 197-225.
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